EP0991285A2 - Communication mobile capable d'éviter la congestion de traitement d'appels - Google Patents

Communication mobile capable d'éviter la congestion de traitement d'appels Download PDF

Info

Publication number: EP0991285A2
Authority: EP; European Patent Office
Prior art keywords: call processing; base station; processor; base stations; mobile communication
Prior art date: 1998-09-11
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Withdrawn

Application number

EP19990117497

Other languages

German (de)

English (en)

Other versions

EP0991285A3 (fr

Inventor

Koji Fujimoto

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

NEC Corp

Original Assignee

NEC Corp

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

1998-09-11

Filing date

1999-09-13

Publication date

2000-04-05

1999-09-13 Application filed by NEC Corp filed Critical NEC Corp

2000-04-05 Publication of EP0991285A2 publication Critical patent/EP0991285A2/fr

2001-04-11 Publication of EP0991285A3 publication Critical patent/EP0991285A3/fr

Status Withdrawn legal-status Critical Current

Links

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238000012546 transfer Methods 0.000 claims description 17
238000004891 communication Methods 0.000 claims description 16
230000005856 abnormality Effects 0.000 claims description 6
238000010586 diagram Methods 0.000 description 17
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101001089083 Daboia russelii C-type lectin domain-containing protein 2 Proteins 0.000 description 2
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Classifications

- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04Q—SELECTING
- H04Q11/00—Selecting arrangements for multiplex systems
- H04Q11/04—Selecting arrangements for multiplex systems for time-division multiplexing
- H04Q11/0428—Integrated services digital network, i.e. systems for transmission of different types of digitised signals, e.g. speech, data, telecentral, television signals
- H04Q11/0478—Provisions for broadband connections
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W36/00—Hand-off or reselection arrangements
- H04W36/0005—Control or signalling for completing the hand-off
- H04W36/0055—Transmission or use of information for re-establishing the radio link
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L12/00—Data switching networks
- H04L12/54—Store-and-forward switching systems
- H04L12/56—Packet switching systems
- H04L12/5601—Transfer mode dependent, e.g. ATM
- H04L2012/5603—Access techniques
- H04L2012/5604—Medium of transmission, e.g. fibre, cable, radio
- H04L2012/5607—Radio
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L12/00—Data switching networks
- H04L12/54—Store-and-forward switching systems
- H04L12/56—Packet switching systems
- H04L12/5601—Transfer mode dependent, e.g. ATM
- H04L2012/5619—Network Node Interface, e.g. tandem connections, transit switching
- H04L2012/562—Routing
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L12/00—Data switching networks
- H04L12/54—Store-and-forward switching systems
- H04L12/56—Packet switching systems
- H04L12/5601—Transfer mode dependent, e.g. ATM
- H04L2012/5629—Admission control
- H04L2012/563—Signalling, e.g. protocols, reference model

Definitions

This invention relates to a mobile communication method and a mobile communication system in which technique of an asynchronous transfer mode (ATM) multiplexing is applied or used to a transmission between a base station and an exchange station or a base station control apparatus.
ATM asynchronous transfer mode
the STM multiplexing is one of a time division multiplexing (TDM) system and is a system which periodically distributes time-divided channels into which an original channel is temporality divided.
TDM time division multiplexing
the STM multiplexing has a frame structure in which each frame is divided into a plurality of time slots.
the transmission path interface in the STM multiplexing a 1.5Mbit/s highway interface or a 2Mbit/s highway interface.
the 1.5Mbit/s highway interface has a frame structure in which each frame is divided into twenty-four time slots while the 2Mbit/s highway interface has a frame structure in which each frame is divided into thirty-two time slots.
one time slot in each frame is exclusively assigned for control of the base station.
two time slots in each frame may be exclusively assigned for control of the base station for redundancy structure.
the mobile communication exchange station is provided with a plurality of base station control signal terminating equipments which are fixedly connected to host call processing processors in one-to-one correspondence fashion.
the base stations are connected to the base station control signal terminating equipments in one-to-one correspondence fashion. Accordingly, connection between a base station and a call processing processor has a structure of one-to-one connection fashion.
JP-A 10-042337 is a mobile communication system which performs ATM transmission of data transfer between a base station and a mobile communication exchange station.
JP-A 10-042337 it is possible for the mobile communication system to execute site diversity to a mobile station during soft handover and to execute selective synthesis of received signals in low delay in the mobile communication exchange station. Transmitted from base stations to a mobile communication exchange station in layered cells, received data are received in ATM cell receiving arrangements and thereafter decomposed into short cells in short cell converting arrangements.
a distributing arrangement distributes short cells including received data from a mobile station during soft handover.
a frame sorting arrangement obtains short cells including received data of every user, the short cells are supplied to frame selecting arrangements to select the received data having larger likelihood.
the mobile communication system disclosed in JP-A 10-042337 does not take congestion of call, processing and transmission efficiency between the base station and the mobile communication exchange station into consideration.
JP-A 09-322235 Another mobile communication system is disclosed in Japanese Unexamined Patent Publication of Tokkai No. Hei 9-322,235 or JP-A 09-322235.
JP-A 09-322235 it is possible to provide a mobile communication system in which the transmission efficiency of an ATM link in the system is enhanced.
the mobile comication system according to JP-A 09-322235 is composed of a portable set (PS), base stations (BSs), and a mobile exchange center (MSC).
PS portable set
BSs base stations
MSC mobile exchange center
site diversity every frame is carried out by using ATM links between the base stations and the mobile exchange center.
the base station is provided with a frame transfer discrimination arrangement for discriminating whether a frame received from the portable set is aborted or is transferred to the mobile exchange center based on reliability information and with a threshold storage arrangement for storing a threshold used for discrimination of the frame transfer discrimination arrangement.
a frame with low reliability is aborted by the base station and it is therefore possible to make the transmission between the base stations and the mobile exchange center efficient.
the mobile communication system disclosed in JP-A 09-322235 does not take congestion of call processing and overhead of a call processing processor in an exchange station or in a base station control apparatus into consideration.
a mobile communication method is for use in a mobile communication system for carrying out transmission between a plurality of base stations and an exchange station using an asynchronous transfer mode (ATM).
the exchange station includes N call processing processors where N represents a positive integer which is not less than two.
the mobile communication method comprises the steps of establishing N call processing virtual connection links between each of the stations and the exchange station, and of controlling, in response to outgoing calls successively generated by said base stations, the call processing by the N call processing processors in order by changing the N call processing virtual connection links in order.
a mobile communication method is for use in a mobile communication system for carrying out transmission between a plurality of base stations and a base station control apparatus using an asynchronous transfer mode (ATM).
the base station control apparatus includes N call processing processors where N represents a positive integer which is not less than two.
the mobile communication method comprises the steps of establishing N call processing virtual connection links between each of the base stations and the exchange station, and of controlling, in response to outgoing calls successively generated by the base stations, the call processing by the N call processing processors in order by changing the N call processing virtual connection links in order.
a mobile communication method is for use in a mobile communication system comprising a mobile station, a plurality of base stations, and an exchange station connected to the base stations.
the exchange station comprises N call processing processors where N represents a positive integer which is not less than two.
the mobile communication method comprises the steps of informing, on reception of an outgoing call for the mobile station, the mobile station of an node number for identifying the exchange station actually connected to the mobile station via a particular base station and a processor number for identifying the call processing processor actually carrying out a call processing to make the mobile station hold the node number and the processor number as a held node number and a held processor number, of sending, when the mobile station carries out handover, the held node number and the held processor number from the mobile station to a new base station destined for the handover, and of selecting, in the exchange station managing the new base station, a call processing processor in accordance with load distribution order to make the call processing processor inherit a call processing.
a mobile communication method is for use in a mobile communication system comprising a mobile station, a plurality of base stations, a base station control apparatus for controlling the base stations, and an exchange station connected to the base station control apparatus.
the base station control apparatus comprises N call processing processors where N represents a positive integer which is not less than two.
the mobile communication method comprises the steps of informing, on reception of an outgoing call for the mobile station, the mobile station of a node number for identifying said base station control apparatus actually connected to the mobile station via a particular base station and a processor number for identifying the call processing processor actually carrying out a call processing to make the mobile station hold the node number and the processor number as a held node number and a held processor number, of sending, when the mobile station carries out handover, the held node number and the held processor number from the mobile station to a new base station destined for the handover, and of selecting, in the base station control apparatus managing the new base station, a call processing processor in accordance with load distribution order to make the call processing processor inherit a call processing.
a mobile communication system is for carrying out transmission between a plurality of base stations and an exchange station using an asynchronous transfer mode (ATM).
the exchange station comprises a plurality of primary ATM interfaces for carrying out connection of the base stations and another node, an ATM switch, N call processing processors for carrying out call control processing, where N represents a positive integer which as not less than two, a common signaling processing processor for carrying out communication control between the other node and the exchange station, an operational maintenance processor for managing the N call processing processors and the common signaling processing processor and for carrying out a path setting control for the ATM switch, and a plurality of primary base station control signal terminating equipments, disposed between the ATM switch and respective ones of the N call processing processors, the common signaling processing processor, and the operational maintenance processor, for setting links between each of the base stations and the other node and the exchange station.
ATM switch asynchronous transfer mode
Each of the base stations comprises a radio interface section for radio communication between the mobile station and the base station in question, a secondary base station control signal terminating equipment for establishing an operational maintenance virtual connection link between the operational maintenance processor and the secondary base station control signal terminating equipment and N call processing virtual connection links between the N call processing processors and the secondary base station control signal terminating equipment, a central processing unit for controlling the radio interface section and the secondary base station control signal terminating equipment to select the call processing virtual connection link in order in response to an outgoing call, a secondary ATM interface for carrying out connection between the exchange station and the base station in question, and a multiplexing and demultiplexing unit for multiplexing and demultiplexing signals between the secondary ATM interface and the radio interface section and the secondary base station control signal terminating equipment.
a mobile communication system is for carrying out transmission between a plurality of base stations and a base station control apparatus using an asynchronous transfer mode (ATM).
the base station control apparatus comprises a plurality of primary ATM interfaces for carrying out connection of the base stations and another node, an ATM switch, N call processing processors for carrying out call control processing, where N represents a positive integer which is not less than two, a common signaling processing processor for carrying out communication control between the another node and the base station control apparatus, an operational maintenance processor for managing the N call processing processors and the common signaling processing processor and for carrying out a path setting control for the ATM switch, primary base station control signal terminating equipments, disposed between the ATM switch and respective ones of the N call processing processors, the common signaling processing processor, and the operational maintenance processor, for setting links between each of the base station and the other node and the base station control apparatus.
ATM switch asynchronous transfer mode
Each of the base stations comprises a radio interface section for radio communication between the mobile station and the base station in question, a secondary base station control signal terminating equipment for establishing an operational maintenance virtual connection link between the operational maintenance processor and the secondary base station control signal terminating equipment and call processing virtual connection links between the N call processing processors and the secondary base station control signal terminating equipment, a central processing unit for controlling the radio interface section and the secondary base station control signal terminating equipment to select the call processing virtual connection link in order in response to an outgoing call, a secondary ATM interface for carrying out connection between the exchange station and the base station in question, and a multiplexing and demultiplexing unit for multiplexing and demultiplexing signals between the secondary ATM interface and the radio interface section and the secondary base station control signal terminating equipment.
the illustrated mobile communication system comprises a mobile station (MS) 20, a plurality of base stations (BTS) 30, a mobile communication exchange station (MSC) 40 for controlling the base stations 30.
the mobile communication system comprises four base stations 30, namely, first through fourth base stations (BTS1, BTS2, BTS3, and BTS4) 30-1, 30-2, 30-3, and 30-4.
the mobile communication exchange station 40 comprises a plurality of processors 41, 42, and 43, an asynchronous transfer mode (ATM) switch (ATM-SW) 44, a plurality of primary ATM interfaces (AIN) 45, and a plurality of primary base station control signal terminating equipments (L2C) 46 in the manner which will become clear as the description proceeds.
ATM asynchronous transfer mode
ATM-SW asynchronous transfer mode switch
AIN primary ATM interfaces
L2C primary base station control signal terminating equipments
processors 41 to 43 are classified into three types or groups.
a first type of processor is an operational maintenance processor (OMP) depicted at 41.
a second type of processors are N call processing processors (CLP) depicted at 42, where N represents a positive integer which is not less than two.
a third type of processor is a common signaling processing processor (CSP) depicted at 43.
the operational maintenance processor 41, the N call processing processors 42, and the common signaling processing processor 43 can carry out interprocessor communication.
the positive integer N is equal to two. Accordingly, two call processing processors will be hereinafter called first and second call processing processors (CLP0, CLP1) 42-1 and 42-2.
the operational maintenance processor 41 manages the first and the second call processing processors 42-1 and 42-2 and carries out a path setting control for the ATM switch 44.
Each of the first and the second call processing processors 42-1 and 42-2 carries out call control processing.
the common signaling processing processor 43 carries out communication control between another node (not shown).
Layers 1,2,3,4,5,6, and 7 which are called the physical layer, the data link layer, the network layer, the transport layer, the session layer, the presentation layer, and the application layer.
Layers 1,2,3,4,5,6, and 7 which are called the physical layer, the data link layer, the network layer, the transport layer, the session layer, the presentation layer, and the application layer.
the ATM layer and the ATM adaptation layer are roughly analogous parts of the data link layer or Layer 2 of the OSI reference model.
the ATM physical layer is analogous to the physical layer or Layer 1 of the OSI reference model.
Layers 1 though 3 in the OSI reference model may be merely called Layers 1 through 3.
the primary ATM interfaces 45 are equal in number to five and will be called first through five primary ATM interfaces (AIN00, AIN01, AIN02, AIN03, AIN04) 45-1, 45-2, 45-3, 45-4, and 45-5.
the first through the fourth primary ATM interfaces 45-1 to 45-4 terminate Layer 1 between the mobile communication exchange unit 40 and the first through the fourth base stations 30-1 to 30-4, respectively.
the fifth primary ATM interface 45-5 terminates Layer 1 between the mobile communication exchange unit 40 and the other node.
Each of the primary base station control signal terminating equipments 46 can control a plurality of protocols in Layer 2.
one of the protocols in Layer 2 is a service specific connection oriented protocol (SSCOP) which is an ATM standard protocol.
the primary base station control signal terminating equipments 46 are assigned to the respective processors and connected to the ATM switch 44. Inasmuch as the processors are equal in number to four in the example being illustrated, the primary base station control signal terminating equipments 46 are equal in number to four and will referred to first through fourth primary base station control signal terminating equipments (L2C00, L2C01, L2C02, and L2C03) 46-1, 46-2, 46-3, and 46-4.
L2C00, L2C01, L2C02, and L2C03 primary base station control signal terminating equipments
Each of the first through the fourth primary base station control signal terminating equipments 46-1 to 46-4 has a plurality of links in the manner which will later become clear.
the first primary base station control signal terminating equipment 46-1 is connected to the operational maintenance processor 41.
the second and the third primary base station control signal terminating equipments 46-2 and 46-3 are connected to the first and the second call processing processors 42-1 and 42-2, respectively.
the fourth primary base station control signal terminating equipment 46-4 is connected to the common signaling processing processor 43.
the ATM switch 44 has a plurality of input/output ports which are equal in number to a total of the processors and the primary ATM interfaces.
the ATM switch 44 has nine input/output ports, namely, first through ninth input/output ports 44 1 , 44 2 , 44 3 , 44 4 , 44 5 , 44 6 , 44 7 , 44 8 , and 44 9 which are assigned with port numbers of #0, #1, #2, #3, #4, #5, #6, #7, and #8, respectively.
the first input/output port 44 1 of the ATM switch 44 is connected to the first primary base station control signal terminating equipment 46-1 for the operational maintenance processor 41.
the second and the third input/output ports 44 2 and 44 3 of the ATM switch 44 are connected to the second and the third primary base station control signal terminating equipments 46-2 and 46-3 for the first and the second call processing processors 42-1 and 42-2, respectively.
the fourth input/output port 44 4 of the ATM switch 44 is connected to the fourth primary base station control signal terminating equipment 46-4 for the common signaling processing processor 43.
the fifth through the eighth input/output ports 44 5 to 44 8 of the ATM switch 44 are connected to the first through the fourth primary ATM interfaces 45-1 to 45-4 for the first through the fourth bass stations 30-1 to 30-4 (Fig. 1), respectively.
the ninth input/output port 44 9 of the ATM switch 44 is connected to the fifth primary ATM interface 45-5 for the other node.
FIG. 3A illustrates each of the first through the third primary base station control signal terminating equipments 46-1 to 46-3 while Fig. 3B illustrates the fourth primary base station control signal terminating equipment 46-4.
each of the first through the third primary base station control signal terminating equipments 46-1 to 46-3 has first through fourth primary links 461, 462, 463, and 464 for the first through the fourth base stations 30-1 to 30-4 (Fig. 1).
the fourth primary base station control signal terminating equipment 46-4 has another primary link 465 for the other node as shown in Fig. 3B.
the base station 30 comprises a central processing unit (CPU) 31, a secondary base station control signal terminating equipment (L2C10) 32, a secondary ATM interface (AIN10) 33, a radio interface section (RI) 34 for radio communication between the mobile station 20 and the base station 30, and a multiplexing and demultiplexing unit (MUX) 35 for multiplexing and demultiplexing a user signal and a control signal.
CPU central processing unit
L2C10 secondary base station control signal terminating equipment
AIN10 secondary ATM interface
RI radio interface section
MUX multiplexing and demultiplexing unit
the central processing unit 31 controls the radio interface section 34 and the secondary base station control signal terminating equipment 32.
the secondary ATM interface 33 terminates Layer 1 between the base station 30 and the mobile communication exchange station 40 (Fig. 1).
the multiplexing and the demultiplexing unit 35 has a function for multiplexing a received user signal from the radio interface section 34 and a received control signal from the secondary base station control signal terminating equipment 32 into a received multiplexed signal to supply the received multiplexed signal to the secondary ATM interface 33.
the multiplexing and the demultiplexing unit 35 also has a function for demultiplexing a transmission multiplexed signal from the secondary ATM interface 33 into a transmission user signal and a transmission control signal to supply the transmission user signal and the transmission control signal to the radio interface section 34 and the secondary radio station control signal terminating equipment 32.
the radio interface section 34 sends the received user signal and the received control signal to the multiplexing and demultiplexing unit 35 and the central processing unit 31, respectively.
the radio interface section 34 receives the transmission user signal and the transmission control signal from the multiplexing and demultiplexing unit 35 and the central processing unit 31, respectively.
the secondary base station control signal terminating equipments 32 can control a plurality of protocols in Layer 2.
one of the protocols in Layer 2 is a service specific connection oriented protocol (SSCOP) which is an ATM standard protocol.
SSCOP service specific connection oriented protocol
the secondary base station control signal terminating equipment 32 is connected to the central processing unit 31.
the secondary base station control signal terminating equipment 32 has first through third virtual connection links (which will be called "VC links") 321, 322, and 323.
the first virtual connection link 321 is for establishing a virtual connection link for the operational maintenance processor 41 of the mobile communication exchange station 40.
the second and the third virtual connection links 322 and 323 are for establishing virtual connection links for the first and the second call processing processors 42-1 and 42-2 of the mobile communication exchange station 40, respectively.
the ATM switch 40 has connection numbers of 0 through 412.
the connection numbers of 0 through 3 are for use in setting SSCOP links between the operational maintenance processor (OMP) 41 and the first through the fourth base stations (BTS1-BTS4) 30-1 to 30-4, respectively.
the connection numbers 4 through 7 are for use in setting SSCOP links between the first call processing processor (CLP0) 42-1 and the first through the fourth base stations (BTS1-BTS4) 30-1 to 30-4, respectively.
the connection numbers 8 through 11 are for use in setting SSCOP links between the second call processing processor (CLP0) 42-2 and the first through the fourth base stations (BTS1-BTS4) 30-1 to 30-4, respectively.
connection number of 12 is for use in setting an SSCOP link between the common signaling processing processor (CSP) 43 and the other node.
the connection numbers of 13 through 412 are for use in setting user signals between the other node and the first through the fourth base stations (BTS1-BTS4) 30-1 to 30-4.
Fig. 7 the description will proceed to operation of the mobile communication system according to the first embodiment of this invention.
attention will be representatively directed to operation between the first base station (BTS1) 30-1 and the mobile communication exchange station (MSC) 40
operations between other base stations (BTS2-BTS4) 30-2 to 30-4 and the mobile communication exchange station (MSC) 40 are similar in a case of the operation between the first base station (BTS1) 30-1 and the mobile communication exchange station (MSC) 40.
the operational maintenance processor (OMP) 41 of the mobile communication exchange station (MSC) 40 performs path setting for the ATM switch 44 illustrated in Fi.6 when the system starts.
the secondary base station control signal terminating equipment (L2C10) 32 of the first base station (BTS1) 30-1 sends a first begin signal BGN to the first primary base station control signal terminating equipment (L2C00) 46-1 for the operational maintenance processor (OMC) 41 in order to establish the VC link for the operational maintenance processor (OMC) 41 in the secondary base station control signal terminating equipment (L2C10) 32.
the first primary base station control signal terminating equipment (L2C00) 46-1 for the operational maintenance processor (OMP) 41 receives the first begin signal BGN
the first primary base station control signal terminating equipment (L2C00) 46-1 for the operational maintenance processor (OMP) 41 sends a first begin acknowledgment signal BGNAK to the secondary base station control signal terminating equipment (L2C10) 32 of the first base station (BTS1) 30-1 and reports establishment of the VC link for the first base station (BTS1) 30-1 to the operational maintenance processor (OMP) 41.
the operational maintenance processor (OMP) 41 When the operational maintenance processor (OMP) 41 receives the report of the establishment of the VC link for the first base station (BTS1) 30-1, the operational maintenance processor (OMP) 41 sends, to the first primary base station control signal terminating equipment (L2C00) 46-1, an instruction signal to instruct the first base station (BTS1) in the number of the call processing processors (CLP) of the system and a node number indicative of the mobile communication exchange station (MSC) 40.
the first primary base station control signal terminating equipment (L2C00) 46-1 sendS, to the first base station (BTS1) 30-1, a signal indicative of the number of the call processing processors (CLP) that is equal to two.
the secondary base station control signal terminating equipment (L2C10) sends a second begin signal BGN to the second primary base station control signal terminating equipment (L2C01) 46-2 in order to establish the VC link for the first call processing processor (CLP0) 42-1.
the second primary base station control signal terminating equipment (L2C01) 46-2 receives the second begin signal BGN
the second primary base station control signal terminating equipment (L2C01) sends a second begin acknowledgment signal BGNAK to the secondary base station control signal terminating equipment (L2C10) and reports establishment of the VC link for the first base station (BTS1) 30-1 to the first call processing processor (CLP0) 42-1.
the secondary base station control signal terminating equipment (L2C10) sends a third begin signal BGN to the third primary base station control signal terminating equipment (L2C02) 46-3 in order to establish the VC link for the second call processing processor (CLP1) 42-2.
the third primary base station control signal terminating equipment (L2C02) 46-3 receives the third begin signal BGN
the third primary base station control signal terminating equipment (L2C02) sends a third begin acknowledgment signal BGNAK to the secondary base station control signal terminating equipment (L2C10) and reports establishment of the VC link for the first base station (BTS1) 30-1 to the second call processing processor (CLP1) 42-2.
the first base station (BTS1) 30-1 is put into a communicable state where the first base station (BTS1) 30-1 communicates with the operational maintenance processor (OMP) 41, the first call processing processor (CLP0) 42-1, and the second call processing processor (CLP1) 42-2.
the other base stations (BTS2-BTS4) 30-2 to 30-4 are put into communicable states where the other base stations (BTS2-BTS4) 30-2 to 30-4 communicate with the operational maintenance processor (OMP) 41, the first call processing processor (CLP0) 42-1, and the second call processing processor (CLP1) 42-2.
the first base station (BTS1) 30-1 informs, using the VC link for the first call processing processor (CLP0) 42-1, the first call processing processor (CLP0) 42-1 of a first outgoing call signal indicative of the first outgoing call 1.
the first call processing processor (CLP0) 42-1 carries out interprocessor communication with the common signaling processing processor (CSP) 43 to make the common signaling processing processor (CSP) 43 inquire to the other node.
a replay signal is transferred from the common signaling processing processor (CSP) 43 to the first call processing processor (CLP0) 42-1.
An acceptance signal for the first outgoing call 1 is sent from the first call processing processor (CLP0) 42-1 to the first base station (BTS1) via the second primary base station control signal terminating equipment (L2C01) 46-2.
the call processing for the first outgoing call 1 is made in the first call processing processor (CLP0) 42-1.
the VP links to be used are rotated in order and the outgoing call signals are equally sent to the first and the second call processing processors (CLP0, CLP1) 42-1 and 42-2. As a result, it is possible to equalize load balance.
a base station detects that a failure occurs in a VP link for a call processing processor. Under the circumstances, the base station carries out processing so as to remove the VP link in question from assignment rotation.
the operational maintenance processor (OMP) 41 confirms or makes a health check whether or not the call processing processors (CLP) normally operate. More specifically, the operational maintenance processor (OMP) 41 periodically sends a request message to the call processing processors (CLP). When each call processing processor (CLP) receives the request message, the call processing processor (CLP) sends a replay massage corresponding to the request message to the operational maintenance processor (OMP) 41. If the operational maintenance processor (OMP) 41 receives the replay massage, the operational maintenance processor (OMP) 41 determines that the call processing processor (CLP) in question normally operates. In the operational maintenance processor (OMP) 41 does not receive the replay massage within a predetermined time interval, the operational maintenance processor (OMP) 41 determines that a failure occurs in the call processing processor (CLP) in question.
the operational maintenance processor (OMP) 41 determines that a failure occurs in the call processing processor (CLP) in question.
the operational maintenance processor (OMP) 41 detects abnormality in the call processing processor (CLP)
the operational maintenance processor (OMP) 41 instructs, using the VC link for the operational maintenance processor (OMC), each base station (BTS) to disable the call processing processor (CLP) in question. Accordingly, each base station (BTS) never uses a nonusable link for the abnormality of the call processing processor (CLP).
the VC link for the operational maintenance processor (OMC) may be preferably duplicated.
the illustrated mobile communication system comprises the mobile station (MS) 20, the plurality of base stations (BTS) 30, a base station control apparatus (BSC) 50 for the base stations 30, and a mobile communication exchange station (MSC) 40A connected to the base station control apparatus 50.
the mobile communication system comprises four base stations 30, namely, the first through the fourth base stations (BTS1, BTS2, BTS3, and BTS4) 30-1, 30-2, 30-3, and 30-4.
the base station control apparatus 50 is similar in structure and operation to the mobile communication exchange station 40 illustrated in Fig. 2. That is, the base station control apparatus 50 comprises a plurality of processors 51, 52, and 53, an asynchronous transfer mode (ATM) switch (ATM-SW) 54, a plurality of primary ATM interfaces (AIN) 55, and a plurality of primary base station control signal terminating equipments (L2C) 56 in the manner which will become clear as the description proceeds.
ATM asynchronous transfer mode
AIN primary ATM interfaces
L2C primary base station control signal terminating equipments
processors 51 to 53 are classified into three types or groups.
a first type of processor is an operational maintenance processor (OMP) depicted at 51.
a second type of processors are N call processing processors (CLP) depicted at 52, where N represents a positive integer which is not less than two.
a third type of processor is a common signaling processing processor (CSP) depicted at 53.
the operational maintenance processor 51, the N call processing processors 52, and the common signaling processing processor 53 can carry out interprocessor communication.
the positive integer N is equal to two. Accordingly, two call processing processors will be hereinafter called first and second call processing processors (CLP0, CLP1) 52-1 and 52-2.
the operational maintenance processor 51 manages the first and the second call processing processors 52-1 and 52-2 and carries out a path setting control for the ATM switch 54. Each of the first and the second call processing processors 52-1 and 52-2 carries out call control processing.
the common signaling processing processor 53 carries out communication control between another node (not shown).
the primary ATM interfaces 55 are equal in number to five and will be called first through five primary ATM interfaces (AIN00, AIN01, AIN02, AIN03, AIN04) 55-1, 55-2, 55-3, 55-4, and 55-5.
the first through the fourth primary ATM interfaces 55-1 to 55-4 terminate Layer 1 between the base station control apparatus 50 and the first through the fourth base stations 30-1 to 30-4, respectively.
the fifth primary ATM interface 55-5 terminates Layer 1 between the base station control apparatus 50 and the other node.
Each of the primary base station control signal terminating equipments 56 can control a plurality of protocols in Layer 2.
one of the protocols in Layer 2 is a service specific connection oriented protocol (SSCOP) which is an ATM standard protocol.
the primary base station control signal terminating equipments 56 are assigned to the respective processors and connected to the ATM switch 54.
the primary base station control signal terminating equipments 56 are equal in number to four and will referred to first through fourth primary base station control signal terminating equipments (L2C00, L2C01, L2C02, and L2C03) 56-1, 56-2, 56-3, and 56-4.
Each of the first through the fourth primary base station control signal terminating equipments 56-1 to 56-4 has a plurality of links in the manner which will later become clear.
the first primary base station control signal terminating equipment 56-1 is connected to the operational maintenance processor 51.
the second and the third primary base station control signal terminating equipments 56-2 and 56-3 are connected to the first and the second call processing processors 52-1 and 52-2, respectively.
the fourth primary base station control signal terminating equipment 56-4 is connected to the common signaling processing processor 53.
the ATM switch 54 has a plurality of input/output ports which are equal in number to a total of the processors and the primary ATM interfaces.
the ATM switch 54 has nine input/output ports, namely, first through ninth input/output ports 54 1 , 54 2 , 54 3 , 54 4 , 54 5 , 54 6 , 54 7 , 54 8 , and 54 9 which are assigned with port numbers of #0, #1, #2, #3, #4, #5, #6, #7, and #8, respectively.
the first input/output port 54 1 of the ATM switch 54 is connected to the first primary base station control signal terminating equipment 56-1 for the operational maintenance processor 51.
the second and the third input/output ports 54 2 and 54 3 of the ATM switch 54 are connected to the second and the third primary base station control signal terminating equipments 56-2 and 56-3 for the first and the second call processing processors 52-1 and 52-2, respectively.
the fourth input/output port 54 4 of the ATM switch 54 is connected to the fourth primary base station control signal terminating equipment 56-4 for the common signaling processing processor 53.
the fifth through the eighth input/output ports 54 5 to 54 8 of the ATM switch 54 are connected to the first through the fourth primary ATM interfaces 55-1 to 55-4 for the first through the fourth base stations 30-1 to 30-4 (Fig. 8), respectively.
the ninth input/output port 54 9 of the ATM switch 54 is connected to the fifth primary ATM interface 55-5 for the other node.
FIG. 10A illustrates each of the first through the third primary base station control signal terminating equipments 56-1 to 56-3 while Fig. 10B illustrates the fourth primary base station control signal terminating equipment 56-4.
each of the first through the third primary base station control signal terminating equipments 56-1 to 56-3 has first through fourth primary links 561, 562, 563, and 564 for the first through the fourth base stations 30-1 to 30-4 (Fig. 8).
the fourth primary base station control signal terminating equipment 56-4 has another primary link 565 for the other node as shown in Fig. 10B.
the central processing unit 31 of the base station (BTS) 30 transmits, to the mobile station (MS) 20 via the radio interface section (RI) 34, an outgoing call acceptance signal with the identification number of the call processing processor (CLP) currently used for the mobile station (MS) 20 and the node number attached to the outgoing call acceptance signal.
the identification number of the call processing processor (CLP) is hereinafter called a "CLP number.”
the node number is a number for identifying the mobile communication exchange station (MSC) 40 which is currently connected to the mobile station (MS) 20 in a case of the first embodiment of this invention illustrated in Fig. 1 while the node number is a number for identifying the base station control apparatus (BSC) 50 which is currently connected to the mobile station (MS) 20 in a case of the second embodiment of this invention illustrated in Fig. 8.
the mobile station (MS) 20 stores or holds the informed CLP number and the informed node number as a held CLP number and a held node number.
the mobile station (MS) 20 transmits a handover request message to a new base station (BTS) with the held CLP number and the held node number attached to the handover request message.
the new base station (BTS) determines, in accordance with the node number within the handover request message, that the handover is that within the same mobile communication exchange station (MSC) 40 or within the same base station control apparatus (BSC) 50.
the new base station (BTS) sends, in accordance with the held CLP number within the handover request message, the message to the same call processing processor (CLP) with its connection.
the new base station (BTS) sends, in accordance with order in load distribution, the message to a call processing processor (CLP) by allocating connections in order in the similar manner in the outgoing call.
the mobile station (MS) 20 when the mobile station (MS) 20 carries out the handover, it is possible to use the same call processing processor (CLP) on the outgoing call in a case where the handover is that within the same mobile communication exchange station (MSC) 40 or within the same base station control apparatus (BSC) 50.
the handover is that between different mobile communication exchange stations (MSC) or between different base station control apparatuses (BSC)
CLP call processing processor
FIGs. 11 and 12 show system structures in a case of the mobile communication system according to the first embodiment of this invention illustrated in Fig. 1 while Figs. 13 to 15 show system structures in another case of the mobile communication system according to the second embodiment of this invention illustrated in Fig. 8.
Fig. 11 shows a case where the mobile station (MS) 20 makes a handover from the first base station (BTS1) 30-1 to the second base station (BTS2) 30-2 and the first and the second base stations 30-1 and 30-2 are connected to the same mobile communication exchange station (MSC) 40. Under the circumstances, the same call processing processor (CLP) is used in the mobile communication exchange station (MSC) 40.
CLP call processing processor
Fig. 12 shows another case where the mobile station (MS) 20 makes a handover from the first base station (MTS1) 30-1 to the second base station (BTS2) 30-2 and the first and the second base stations 30-1 and 30-2 are connected to first and second mobile communication exchange stations (MSC1, MSC2) 40-2 and 40-2, respectively.
a new call processing processor (CLP) is used, in accordance with order of the load distribution, in the second mobile communication exchange station (MSC2) 40-2.
CLP call processing processor
Fig. 13 shows a case where the mobile station (MS) 20 makes a handover from the first base station (BTS1) 30-1 to the second base station (BTS2) 30-2 and the first and the second base stations 30-1 and 30-2 are connected to the same base station control apparatus (BSC) 50. Under the circumstances, the same call processing processor (CLP) is used in the base station control apparatus (BSC) 50.
CLP call processing processor
Fig. 14 shows another case where the mobile station (MS) 20 makes a handover from the first base station (MTS1) 30-1 to the second base station (BTS2) 30-2 and the first and the second base stations 30-1 and 30-2 are connected to first and second base station control apparatuses (BSC1, BSC2) 50-1 and 50-2, respectively, which are connected to the same mobile communication exchange station (MSC) 40A.
a new call processing processor (CLP) is used, in accordance with order of the load distribution, in the second base station control apparatus (BSC2) 50-2.
Fig. 15 shows still another case where the mobile station (MS) 20 makes a handover from the first base station (MTS1) 30-1 to the second base station (BTS2) 30-2 and the first and the second base stations 30-1 and 30-2 are connected to first and second base station control apparatuses (BSC1, BSC2) 50-1 and 50-2, respectively, which are connected to first and second mobile communication exchange stations (MSC1, MSC2) 40A-1 and 40A-2, respectively.
a new call processing processor is used, in accordance with order of the load distribution, in the second base station control apparatus (BSC2) 50-2 in the manner which is described in conjunction with Fig. 14.
Fig. 16 is a sequence diagram showing an operation example of the handover of a mobile station initiative type in the mobile communication system illustrated in Fig. 8.
the handover of the mobile station initiative type is a handover where a base station to be changed receives a handover request from a mobile station.
the handover is that within the same base station control apparatus (BSC) 50.
the illustrated mobile communication system comprises first through third mobile stations MS1, MS2, and MS3, first and second base stations BTS1 and BTS2, and a base station control apparatus BSC connected to the first and the second base stations BTS1 and BTS2.
the base station control apparatus BSC comprises first and second call processing processors CLP0 and CLP2.
the first and the second call processing processors CLP0 and CLP1 are assigned with the CLP numbers of 0 and 1, respectively.
the base station control apparatus BSC is assigned with, as the node number, a BSC number of 0.
the first through the third mobile stations MS1 to MS3 lie a first cell where the first base station BTS1 covers.
the first base station BTS1 when the first base station BTS1 receives a first outgoing call signal from the first mobile station MS1, the first base station BTS1 sends the first outgoing call signal to the first call processing processor CLP0 in the base station control apparatus BSC.
the first call processing processor CLP0 sends, to the first base station BTS1, a first incoming call acceptance signal with the CLP number of 0 and the BSC number of 0.
the first base station BTS1 sends, to the first mobile station MS1, the first incoming call acceptance signal with the CLP number of 0 and the BSC number of 0.
the first mobile station MS1 stores or holds the CLP number of 0 and the BSC number of 0 as a held CLP number and a held BSC number.
the first base station MTS1 receives a second outgoing call signal from the second mobile station MS2, the first base station MTS2 sends the second outgoing call signal to the second call processing processor CLP1 in the base station control apparatus BSC.
the second call processing processor CLP1 send, to the first base station BTS1, a second incoming call acceptance signal with the CLP number of 1 and the BSC number of 0.
the first base station BTS1 sends, to the second mobile station MS2, the second incoming call acceptance signal with the CLP number of 1 and the BSC number of 0.
the second mobile station MS2 stores or holds the CLP number of 1 and the BSC number of 0 as a held CLP number and a held BSC number.
the first base station BTS1 When the first base station BTS1 receives a third outgoing call signal from the third mobile station MS3, the first base station BTS1 sends the third outgoing call signal to the first call processing processor CLP0 in the base station control apparatus BSC.
the first call processing processor CLP0 sends, to the first base station BTS1, a third incoming call acceptance signal with the CLP number of 0 and the BSC number of 0.
the first base station BTS1 sends, to the third mobile station MS3, the third incoming call acceptance signal with the CLP number of 0 and the BSC number of 0.
the third mobile station MS3 stores or holds the CLP number of 0 and the BSC number of 0 as a held CLP number and a hold BSC number.
the first mobile station MS1 moves from the first cell toward a second cell where the second base station BTS2 covers.
the first mobile station MS1 sends, to the second base station BTS2, a first handover request signal with the held CLP number of 0 and the held BSC number of 0.
the second base station BTS2 sends, to the first call processing processor CLP0 in the base station control apparatus BSC, the first handover request signal with the held CLP number of 0 and the held BSC number of 0.
the first call processing processor CLP0 in the base station control apparatus BSC sends a first handover acceptance signal to the second base station BTS2 with the CLP number and the BSC number attached to the first handover acceptance signal.
the second base station BTS2 sends, to the first mobile station MS1, the first handover acceptance signal with the CLP number and the BSC number.
the first mobile station MS1 stores or holds the CLP number and the BSC number as a held CLP number and a held BSC number.
the second mobile station MS2 moves from the first cell toward the second cell.
the second mobile station MS2 sends, to the second base station BTS2, a second handover request signal with the held CLP number of 1 and the held BSC number of 0.
the second base station BTS2 sends, to the second call processing processor CLP1 in the base station control apparatus BSC, the second handover request signal with the held CLP number of 1 and the held BSC number of 0.
the second call processing processor CLP1 in the base station control apparatus BSC sends a second handover acceptance signal to the second base station BTS2 with the CLP number and the BSC number attached to the second handover acceptance signal.
the second base station BTS2 sends, to the second mobile station MS1, the second handover acceptance signal with the CLP number and the BSC number.
the second mobile station MS2 stores or holds the CLP number and the BSC number as a held CLP number and a held BSC number.
Fig. 17 is a sequence diagram showing an operation example of the handover of a mobile station assist type in the mobile communication system illustrated in Fig. 8.
the illustrated mobile communication system comprises a first mobile station MS1, first through third base stations BTS1, BTS2, and BTS3, and first and second base station control apparatuses BSC0 and BSC1 which include first and second call processing processors CLP0 and CLP2, respectively.
the first and the second call processing processors CLP0 and CLP1 are assigned with the CLP numbers of 0 and 1, respectively.
the first and the second base station control apparatuses BSC0 and BSC0 are assigned with node numbers of 0 and 1, respectively.
the first through the third base stations BTS1 to BTS3 cover first through third cells, respectively.
the first through the third base stations BTS1 to BTS3 are connected to the first base station control apparatus BSC0.
the first mobile station MS1 lies in the first cell.
the first mobile station MS1 sends an incoming call signal to the first base station BTS1.
the first base station BTS1 sends the incoming call signal to the first call processing processor CLP0 in the first base station control apparatus BSC0.
the first call processing processor CLP0 in the first base station control apparatus BSC0 sends, to the first base station BTS1, an incoming call acceptance signal with the CLP number of 0 and the node number of 0.
the first base station BTS1 sends the incoming call acceptance signal with the CLP number of 0 and the node number of 0 to the first mobile station MS1.
the first mobile station MS1 stores or holds the CLP number of 0 and the node number of 0 as a held CLP number and a held node number.
the first base station BTS1 sends, to the second call processing processor CLP1 in the second base station control apparatus BSC1, a handover report signal including a list of the base stations to be exchanged.
the first call processing processor CLP0 in the first base station control apparatus BSC0 sends, to the first base station BTS1, a handover instruction signal indicative of the third base station BST3 to be exchanged.
the first base station BTS1 sends the handover instruction signal to the first mobile station MS1.
the first mobile station MS1 executes the handover and transmits, to the third base station BTS3, a handover execution signal with the held CLP number and the held node number.
the third base station BTS3 sends the handover execution signal with the held CLP number and the held node number to the first call processing processor CLP0 in the first base station control apparatus BSC0.
the first call processing processor CLP0 in the first base station control apparatus BSC0 sends, to the first mobile station MS1 via the third base station BTS3, a handover acceptance signal with the CLP number of 0 and the node number of 0.
the first and the second base stations BTS1 and BTS2 are connected to the first base station control apparatus BSC0 while the third base station BTS3 is connected to the second base station control apparatus BSC1.
the first mobile station MS1 lies in the first cell.
the first mobile station MS1 sends an incoming call signal to the first base station BTS1.
the first base station BTS1 sends the incoming call signal to the first call processing processor CLP0 in the first base station control apparatus BSC0.
the first call processing processor CLP0 in the first base station control apparatus BSC0 sends, to the first base station BTS1, an incoming call acceptance signal with the CLP number of 0 and the node number of 0.
the first base station BTS1 sends the incoming call acceptance signal with the CLP number of 0 and the node number of 0 to the first mobile station MS1.
the first mobile station MS1 stores or holds the CLP number of 0 and the node number of 0 as a held CLP number and a held node number.
the first base station BTS1 sends, to the second call processing processor CLP1 in the second base station control apparatus BSC1, a handover report signal including a list of the base stations to be exchanged.
the first call processing processor CLP0 in the first base station control apparatus BSC0 sends, to the first base station BTS1, a handover instruction signal indicative of the third base station BST3 to be exchanged.
the first base station BTS1 sends the handover instruction signal to the first mobile station MS1.
the first mobile station MS1 executes the handover and transmits, to the third base station BTS3, a handover execution signal with the held CLP number of 0 and the held node number of 0.
the third base station BTS3 sends the handover execution signal with the held CLP number and the held node number to the second call processing processor CLP1 in the second base station control apparatus BSC1.
the second call processing processor CLP1 in the second base station control apparatus BSC1 sends, to the first mobile station MS1 via the third base station BTS3, a handover acceptance signal with the CLP number of 1 and the node number of 1.

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Engineering & Computer Science (AREA)
Computer Networks & Wireless Communication (AREA)
Signal Processing (AREA)
Mobile Radio Communication Systems (AREA)
Data Exchanges In Wide-Area Networks (AREA)

EP19990117497 1998-09-11 1999-09-13 Communication mobile capable d'éviter la congestion de traitement d'appels Withdrawn EP0991285A3 (fr)

Applications Claiming Priority (2)

Application Number	Priority Date	Filing Date	Title
JP25877598A JP3092600B2 (ja)	1998-09-11	1998-09-11	移動通信方法及び移動通信システム
JP25877598		1998-09-11

Publications (2)

Publication Number	Publication Date
EP0991285A2 true EP0991285A2 (fr)	2000-04-05
EP0991285A3 EP0991285A3 (fr)	2001-04-11

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US (1)	US6463045B1 (fr)
EP (1)	EP0991285A3 (fr)
JP (1)	JP3092600B2 (fr)
KR (1)	KR100304777B1 (fr)
CN (1)	CN1230010C (fr)
BR (1)	BR9908665A (fr)

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KR20010097104A (ko) *	2000-04-20	2001-11-08	박종섭	아이엠티-2000 제어국에서 에이티엠 기반의아이에스-634에이를 이용한 텔리서비스 방법
JP2002101103A (ja) *	2000-09-20	2002-04-05	Nec Saitama Ltd	基地局変復調装置及びａｔｍセル送受信方法
KR100404876B1 (ko) *	2000-11-02	2003-11-07	주식회사 하이닉스반도체	호처리 프로세서의 부하 분산장치 및 그 방법
KR100363883B1 (ko) *	2000-12-18	2002-12-11	한국전자통신연구원	아이엠티-2000 비동기시스템에서의 무선망 제어국
KR20020095573A (ko) *	2001-06-14	2002-12-27	주식회사 하이닉스반도체	아이엠티-2000 시스템에서 에이티엠 자원 할당 방법
JP2007159005A (ja) *	2005-12-08	2007-06-21	Fujitsu Ltd	無線ネットワークシステム及び同システムにおける通信トラフィック切替方法並びに同システムに用いられるトラフィック処理装置、回線多重装置及び上位装置
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KR101806210B1 (ko) *	2017-06-14	2017-12-07	방종갑	3차원 홀로그램 시트로 이루어진 화병

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US6463045B1 (en)	2002-10-08
KR20000023050A (ko)	2000-04-25
JP2000092561A (ja)	2000-03-31
EP0991285A3 (fr)	2001-04-11
JP3092600B2 (ja)	2000-09-25
CN1248136A (zh)	2000-03-22
BR9908665A (pt)	2000-10-17
CN1230010C (zh)	2005-11-30
KR100304777B1 (ko)	2001-11-07

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